Trapped ion modes (TIM) belong to the family of ion temperature gradient (ITG) modes, which are one of the important ingredients in heat turbulent transport at the ion scale in tokamak plasmas. A global linear analysis of a reduced gyro-bounce kinetic model for trapped particle modes is performed, and a spectral method is proposed to solve the dispersion relation. Importantly, the radial profile of the particle drift velocity is taken into account in the linear analysis by considering the magnetic flux $\psi$ dependency of the equilibrium Hamiltonian $H_{eq}$($\psi$) in the quasi-neutrality equation and equilibrium gyro-bounce averaged distribution function $F_{eq}$. Using this spectral method, linear growth-rates of TIM instability in presence of different temperature profiles and precession frequencies of trapped ions, with an approximated constant Hamiltonian and the exact $\psi$ dependent equilibrium Hamiltonian, are investigated. The growth-rate depends on the logarithmic gradient of temperature $\kappa_T$ , density $\kappa_n$ and equilibrium Hamiltonian $\kappa_\Lambda$ With the exact $\psi$ dependent Hamiltonian, the growth rates and potential profiles are modified significantly, compared to the cases with approximated constant Hamiltonian. All the results from the global linear analysis agree with a semi-Lagrangian based linear Vlasov solver with a good accuracy. This spectral method is very fast and requires very less computation resources compared to a linear version of Vlasov-solver based on a semi-Lagrangian scheme